System and method for determining absolute position using a multiple wavelength signal

ABSTRACT

Various aspects of the present invention are shown and described, each of which has stand alone utility in a navigated medical environment. A receiver position calibration system and method facilitates calibration of a reference frame prior to each navigated procedure. A concept and application of confidence weights is introduced. Confidence weights can be applied to distance calculations to mitigate the effects of interference and increase the tolerance of the navigated medical system. Multi-path interference is minimized through the transmission of a signal having a pattern of unique frequencies and filtering of the distance calculations for each frequency to identify the ‘best’ distance in the presence of multi-path interference. A position determination method and system that transmits a signal having multiple frequency components permits positions to be identified with high resolution over a large area.

RELATED APPLICATIONS

This application claims priority under 35 U.S.C. §1.119(e) toprovisional patent application Ser. Nos. 60/823,116 and 60/823,113 filedAug. 22, 2006.

FIELD OF THE INVENTION

This invention relates to generally to the field of navigated surgeryand more particularly to wireless tracking of objects with very fineprecision.

BACKGROUND OF THE INVENTION

There are many applications in which radio frequency (RF) or microwavesignals are used for tracking objects, such as Global PositioningSystems (GPS), Loran, aircraft navigation, military radar, and videomotion capture. All of these use some sort of scheme for detecting thetransit times or phases of the RF or microwave signals, followed by aprocessing or computational subsystem to determine the position andother parameters of the object being tracked.

In some of these applications, such as GPS, Loran, and aircraftnavigation systems, the computational intelligence is mounted on themoving object, and the goal is for the operator of the object todetermine its own position relative to the surrounding environment. Inother applications, the processing capability is attached to theenvironment, and the goal is for people or systems to track multipleobjects as they traverse through the environment.

For example, during navigated medical procedures such as NavigatedSurgery (NS) and Image Guided Surgery (IGS) surgeons use electronicsurgical instrument tracking to accurately track in real time where theinstruments are relative to the patient anatomy during the operation. Bycombining computers and wireless instruments, navigated surgery systemsgive surgeons far more accuracy than ever before. During navigatedmedical procedures, transmitters are mounted on surgical instruments andon bone markers that are attached to a patient's anatomy. Receivers,distributed throughout the operating room, receive signals from thetransmitters and use the signals to track instrument position relativeto patient anatomy. A graphical interface may be used to display therelative positions of transmitting signals and anatomical markers toenable the surgeon to perform precise medical procedures. Alternatively,a computational model of the patient anatomy and the positions andorientations of the instruments may be used to guide robotic procedures.

Because distances in the medical environment are small and precisionrequirements are high, methods based on time differences of arrival ofsignals are not within the state of the art of current electronictechnology. For example in an operating room, the positions of apatient's anatomy and of the surgical instruments must be known to aresolution of less than one millimeter (1 mm) in order forcomputer-assisted or navigated surgery to be viable. Since light travels1 mm in approximately 3×10⁻¹² seconds, times would have to be measuredaccurately and repeatably in fractions of picoseconds, something that isbeyond the scope of current electronic technology.

An alternative method is to measure the angles between the phases of atransmitted signal as it is received at different receiving antennas. Itis possible to measure phase differences with a precision of about 1percent. Therefore, if the wavelength of a transmitted signal is about50 mm (i.e., a frequency of about 5.7 GHz), a phase difference of 1percent translates to a positional precision of about 0.5 mm, whichcorresponds to a desired precision of navigated medical procedures.

Methods based on time measurements have a relatively simple calculation−d=c*t, where d is the distance between the transmitting and receivingantenna, c is the speed of light in air, and t is the travel time of thetransmitted signal. In systems and methods based on phase differences,the computation is more complex. The phase of the received signal mustbe compared with the phase of a reference signal. The difference inthese two phases can be converted into a linear measure, but this is notsufficient to give an absolute distance between the two antennas.

In particular, suppose that  ₁ is the phase angle of the received signal(relative to the reference signal) when the transmitting antenna andreceiving antenna are distance d₁ apart, and suppose that φ₂ is thephase angle of the received signal (relative to the reference signal)when those same two antennas are distance d₂ apart. Then the differencein the two distances is given by

$\begin{matrix}{( {d_{1} - d_{2}} ) = {\frac{1}{2\pi \; f}( {\varphi_{1} - \varphi_{2} + {2\pi \; k_{1,2}}} )}} & ( {{eq}\mspace{14mu} 1} )\end{matrix}$

where f is the frequency of transmission, the angles φ₁ and φ₂ aremeasured in radians, and k_(1,2) is an integer representing the wholenumber of wavelengths in the difference (d₁−d₂). There are many ways ofdetermining k_(1,2), including some innovative ways that are adapted toparticular applications. Likewise, φ₁ and φ₂ can be known relative to areference signal, but the absolute phases of φ₁ and φ₂ are dependentupon the phase delays in the electronics of the transmitter, receiver,and cables. In some applications, particularly medical applicationswhere high precision is required, it is not possible to know these phasedelays. As a result, it is also not possible to know a distance such asd₁ absolutely, but only relative to some other previously knowndistance, such as d₂.

Therefore, in medical applications (and some other applications), anobject must be calibrated by first placing it at a known, fixed locationin a frame of reference to determine the phase difference at thatlocation. The object can then be tracked by noting the change in areceived phase angle and converting this by Equation 1 to a change indistance from the known, fixed location.

The step of placing the object at the known location is called theobject calibration process (or instrument calibration process). Forexample, in some navigated procedures, each instrument must be insertedinto a calibration socket prior to usage, and possibly at times duringthe procedure. During the object calibration process, signals aretransmitted between each antenna on the object and each antenna in thatframe of reference. The differences between the phase angles of thereceived signals and the reference signals are measured and recorded.Collectively, these recorded phase differences are called the phasereference at the origin for that object. All other phase differences(between transmitted signals and reference signals) are then comparedwith the phase reference at the origin in order to determine how fareach antenna has moved since object calibration.

For the purposes of this application, a frame of reference is athree-dimensional geometric coordinate system with respect to whichmotion is observed and with respect to which measurements are made. Itwill be appreciated that different applications may have differentframes of reference. A typical frame of reference is the operating roomin which a navigated medical procedure is performed. However, otherapplications may use a frame of reference attached to a particular partof the patient anatomy, and still others may associate it with a robotictool.

Following the calibration, the motion of the object can be tracked byrepeatedly measuring the changes in the phase angles between thereference signal and the signals detected by each receiver. In a typicalinstallation, the phase angles are measured periodically at intervals ofa small fraction of one second. Provided that the object does not movemore than one wavelength during any interval, the change in the phaseangle observed by a transmitting antenna and a receiving antenna can beconverted into a change in distance between those two antennas. Byknowing the changes in the distances between all of the transmitting andreceiving antennas and by knowing the positions of the antennas on themoving object, the position of that object relative to its point ofcalibration can be determined with a desired degree of precision.

In US Patent Application 2006/0066485, Min teaches a system oftransmitters and receivers that can detect phase differences of therequired precision.

In theory, the change in the position of the object in three-dimensionalspace can be determined from the changes in the phases of the signalreceived by three receivers. However, in practical systems, there are amultiplicity of problems and challenges. Among them are: —

a). While three receivers are theoretically sufficient to preciselylocate the position of an object in three-dimensional space, and morereceivers would be redundant. In practice, different combinations ofthree receivers determine different positions for an object, due to manypossible factors. For example, a receiver may temporarily obstructedfrom line of sight to the object, the electromagnetic field of the RFwaves may be distorted by metal objects or other interference, or theelectronics of one receiver may not be as sensitive as another.

b). The relative positions of the antennas are not typically knownwithin a fraction of a wavelength. In practical environments, someantennas may be many wavelengths apart. For example, in an operatingroom, an array of receiving antennas may be placed 2 meters above thepatient (i.e., about 40 wavelengths) and the array itself may be 2meters in diameter. In some situations, the receiver array may be on aportable cart that is wheeled into position prior to a surgicaloperation. Therefore, some method of calibrating the antennas in theframe of reference is needed before the positions of any objects can bedetermined.

c). Radio and microwave signals are subject to “multipath” distortion.That is, a transmitted signal may take multiple paths to the receiver.It is difficult with these methods to differentiate the straight linesignal from the interference of signals taking other paths. Methods areneeded for filtering out this distortion or for using redundantinformation to accurately discriminate the positions of objects.

d) In practical applications, one or more receivers may “lose sight” ofan object. For example, a person or another object may temporarily getbetween a transmitter and a receiver, or the object may be dropped, or atransmitted signal may be corrupted or badly distorted. In all of thesecases, the continuous tracking of an object from one update cycle toanother is lost, and the absolute position of the object becomesambiguous. Methods are needed to recover the positions of objects lostin this way.

e) A typical application environment will have multiple objects, eachwith multiple transmitters. In many situations, not only must theposition of each object be known but also its orientation. If thegeometry of an object is known exactly, it requires at least threeantennas on the object to determine its orientation. However, if anysignal from any one of those antennas is distorted or blocked, theorientation is lost. Methods are needed to maintain accurate positionand orientation information about all of the objects in the field ofinterest.

f) Some application environments require very frequent updating ofposition and orientation information. For example, in robotic assistedsurgery, all instruments and anatomic markers must refresh positioninformation with frequencies up to 1 kilohertz (1. KHz) or more. Methodsare needed that allow such frequent updating.

It would be desirable to determine a system and method that wouldprovide the precise location and orientation of multiple objects withprecisions of a small fraction of the wavelengths of the transmittedsignals at a frequency that would support robotic assisted surgery.

SUMMARY OF THE INVENTION

According to one aspect of the invention, a method for determining aposition of an object with high resolution over a large area includesthe steps of transmitting a signal between the object and an antenna,the signal having a long wavelength component and a short wavelengthcomponent, deriving coarse distance information from the long wavelengthcomponent of the signal and deriving fine distance information from theshort wavelength component of the signal; and determining the positionof the object using the coarse distance information and fine distanceinformation.

According to another aspect of the invention, a method for determining aposition of an object with high resolution over a large area includesthe steps of transmitting a signal between the object and an antenna,the signal comprising two components differing in frequency by a desiredamount, determining a coarse distance between the object and the antennain response to a difference between the two components of the signal anda fine distance between the object and the antenna using at least one ofthe two components of the signal; and determining a position of theobject in response to the coarse distance and the fine distance.

According to a further aspect of the invention, a system for determininga position of an object with high resolution over a large area includestransmit circuitry for generating a signal for transmission between theobject and an antenna, the signal having a long wavelength component anda short wavelength component, a computer readable medium having programcode stored thereon, the program code operable when executed by aprocessor of the system to derive coarse distance information from thelong wavelength component of the signal and deriving fine distanceinformation from the short wavelength component of the signal anddetermine the position of the object using the coarse distanceinformation and fine distance information.

According to another aspect of the invention, a system for determining aposition of an object with high resolution over a large area includes atransmitter for transmitting a signal between the object and an antenna,the signal comprising two components differing in frequency by a desiredamount, program code stored on a computer readable medium of the systemand operable when executed by a processor of the system to determine acoarse distance between the object and the antenna in response to adifference between the two components of the signal and a fine distancebetween the object and the antenna using at least one of the twocomponents of the signal and determine a position of the object inresponse to the coarse distance and the fine distance.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a block diagram illustrating exemplary components that may beincluded in a navigated medical environment incorporating the invention;

FIGS. 2A and 2B illustrate an example of a transmit antenna assembly andits associated geometry that may advantageously be used with the presentinvention;

FIG. 3 is a block diagram illustrating exemplary components of areceiver of the present invention;

FIG. 4 illustrates exemplary components of a historical data store thatmay be used to generate a confidence weight for a respective transmitantenna/receive antenna pair;

FIG. 5 illustrates components that may be included as part of receiverlogic for generating a confidence weight;

FIG. 6 is a block diagram of a navigated medical system thatincorporates a confidence weight into a position calculation processsuch as that of FIG. 7;

FIG. 7 is a flow diagram illustrating exemplary steps that are performedin a minimization process used to determine a position in the system ofFIG. 1;

FIG. 8 is a flow diagram including exemplary steps that may be taken togenerate a confidence weight;

FIG. 9 is a block diagram illustrating a calibration device of thepresent invention including a a single antenna and a precision movableplatform;

FIG. 10 is a flow diagram illustrating exemplary steps that may beperformed during a minimization process to calibrate antennas in FIG. 9or FIG. 11;

FIG. 11 is a diagram illustrating components of a calibration tool ofthe present invention including multiple antennas with precisely knownlocations;

FIG. 12 is a graph illustrating the effects of multipath interference ona distance calculation;

FIG. 13 is a graph illustrating one embodiment of varying frequencies ofa transmitting signal by incrementally increasing the frequency of thetransmitted signal;

FIG. 14 is a block diagram illustrating components that may be used toestimate a distance using a plurality of phase differences associatedwith each of the frequency steps of the transmitted signal;

FIG. 15 is a graph illustrating a resulting estimated distance derivedusing the plurality of phase differences associated with each of thefrequency steps of the transmitted signal;

FIG. 16 illustrates flow diagrams including exemplary steps that may beperformed by a transmit and receive process implementing the presentinvention;

FIG. 17 illustrates phase ambiguity that may occur when transmittinghigh frequency signals;

FIG. 18 includes diagrams of graphs that illustrate how long and shortwavelengths can be used to resolve a position;

FIG. 19 illustrates one embodiment that may be used to provide a highand low frequency signals to receivers to determine a position with highresolution over a large area; and

FIG. 20 illustrates a second embodiment of transmit circuitry that maybe used to transmit two signals having different wavelengths, where thesignals of FIG. 20 are phase locked to determine a position with highresolution in a large area.

DETAILED DESCRIPTION

FIG. 1 illustrates several components that may be included in anexemplary embodiment of a navigated medical environment 10 in whichvarious aspects of the present invention may advantageously be used toincrease precision of instrument position calculations. As will bedescribed in more detail below, instrument precision can be increased byperforming any one of receiver calibration, alleviation of multipatheffects, the provision of tolerance for line of sight obstruction andthe resolution of absolute position.

In FIG. 1 a surgical navigation system 12 is coupled to a computer 14which includes processing logic and a computer readable medium storingprogram code for use by the navigation system. As will be described inmore detail below, the program code may include any one of the programcodes illustrated in FIG. 1, including absolute positioning code module16, multipath code module 17, line of sight tolerance code module 18 andreceiver calibration code module 19. It should be noted that althoughfour program codes are shown in FIG. 1, it is not a requirement that allfour modules be provided in a navigated medical system; rather it can beappreciated that there are benefits to any system that incorporates anyone of the modules. Accordingly, the present invention is not limited toinclusion of any particular program code module.

The computer 14 is coupled to transmit circuitry 22. The transmitcircuitry 22 provides a signal 27 via distribution block 24 and lead 27a to transmit antenna assembly 26 (comprising antennas 26 a-26 d) thatis mounted on a surgical instrument 23. The signal 27 may also beprovided (via lead 27 b) to transmit antennas on one or more anatomicalmarkers (such as bone marker 29) that are rigidly fastened to thepatient anatomy, wherein the anatomical marker also includes multipletransmit antennas, although they are not shown in FIG. 1 in detail.Finally, reference signal 21 is coupled to receiver circuitry 20.

In FIG. 2A an example of a transmit antenna assembly 129 (FIG. 2A) thatmay be provided on the marker 29 or instrument is shown. FIG. 2B is adiagram illustrating an exemplary geometry of the transmit assembly 129.In one embodiment, each transmit assembly comprises four antennasarranged in a pyramid, with 3 antennas disposed on plane A and thefourth raised off the plane. Each transmit assembly 129 is coupled to acontroller 132, (located either in the transmit circuitry 22 or indistribution box 24) via a shielded wire lead. The leads, shown as agroup 31 in FIG. 2B, are advantageously bundled but individuallyshielded to prevent crosstalk. As shown in FIG. 2B, the antennas aregenerally arranged as a triangular based pyramid, although otherarrangements are possible. Each of the four antennas (129 a, 129 b, 129c, and 129 d) is located at one apex of the pyramid. In an exemplaryembodiment, each edge of the pyramid may measure 2.5 to 5 cm, whichtranslates into 0.5 to 1.0 wavelength of a 5.9 GHz signal. Antennaassemblies may advantageously be packaged in groups of multipleassemblies (four, six or the like) to support navigated medicalenvironments that utilize large numbers of anatomical markers andinstruments. Marker assemblies may be formed from plastic or otherdisposable material with the antenna embedded therein, while antennaassemblies for instruments may be mounted so as to be removable forsterilization.

Referring back to FIG. 1, in some embodiments a distribution block 24may be disposed between the transmitter circuitry and the transmitantenna assemblies 29, 26, although it is not a requirement of theinvention. The distribution block includes an internal switch forswitching the delivery of signal 27 to the antenna assemblies 26 and 29via leads 27 a and 27 b to sequence the transmission of the signal 27among transmitter antennas in the navigated medical environment 10.

The signals transmitted by the transmit assemblies are received by aplurality of receiver antennas 25 a-25 f. The receivers may bedistributed in a spaced semi-circular, circular or other arrangementabove or around the patient. Together the receivers provide a frame ofreference for determining a relative position of each instrument andmarker. One method of calibrating receiver position to provide the frameof reference will be described in more detail below.

The receive antennas 25 a-25 f forward the received signals to receivercircuitry 20. In one embodiment a distance between a receiver antennaand a transmit antenna is determined in response to a measured phasedifference between a reference signal 21 received from the transmitcircuitry 22 and the signals received by receive antennae 25 a-25 f.

Referring briefly to FIG. 3, several components that may be included inan exemplary embodiment of receive circuitry 20 are shown. A receiver300 is associated with each receive antenna. Each receiver 300 includesat least one Phase Discriminator (PD) 302 and at least one analog todigital converter (A/D 304). Each receiver is coupled to receive atleast one reference signal 21 from the transmit circuitry 22. As will bedescribed in more detail below, in one embodiment each receive antennamay receive a signal transmitted at multiple wavelengths to assist inresolution of absolute three dimensional position; in such an embodimentthe receiver would include filters, PDs and A/Ds for each wavelength.(Such an embodiment is described in more detail in FIGS. 17 and 18.) TheA/D 304 of each receiver 300 provides a digitized representation of thephase difference between the reference signal and the associatedreceived signal to the computer 14 via an interface 306. The digitizedphase difference from a particular receiver is used to derive a distancebetween a transmitting antenna and the receiving antenna coupled to thatreceiver. The derived distances are processed by the computer todetermine a three-dimensional position of a transmitting antenna withregard to a frame of reference. It will be appreciated that although thebelow embodiment describes the measurement of distance between areceiver and a transmit antenna using phase difference the presentinvention is not limited to any particular type of measurement. Rather,measured distances can be determined using any variety of techniques,including but not limited to phase discrimination, time difference ofarrival and other means.

Referring back to FIG. 1, according to several aspects of the invention,the computer system comprises a plurality of program modules that areadvantageously used to increase the precision of a three dimensionalposition determination in a navigated medical environment. A ReceiverCalibration (RC) module 16 comprises program code for controlling thetransmission of signals via antennas and the analysis of distancesderived from signals received by antennas to calibrate positions ofreceive antennas for initialization of the system 12. A Line of Sight(LOS) program module 17 gathers and analyzes historical signalcomponents and derived distance data for each receiver to determine aconfidence weight to associate with the receiver's derived distance,thereby alleviating the impact of receiver anomalies. A Multipathprogram code module 18 varies the frequency of the signal 27 to providea signal having a repeating pattern of unique frequencies to minimizethe effects of multipath interference. An Absolute Position (AP) module19 controls the transmission of multiple high frequency signals withstrict phase coherence to increase precision of three dimensionalposition calculations. As will be apparent from the below description,each of the modules may be used independently in any navigated medicalenvironment to improve the precision of position determinations. Eachwill now be described in more detail below.

Tolerance of Obstructions in the Line of Sight

In many applications, it is important to accurately maintain theposition of an object, even when the line of sight between an antennacoupled to the object and one or more of antennas in the frame ofreference is obstructed. Such obstructions occur routinely during thenormal movement of medical personnel during navigated procedures. When areceiver is obstructed, the signal that travels the straight path may beattenuated and the phase angle measurements for that transmitantenna-receiver pair can be compromised.

Mathematically, the tracking of an object in three dimensions using RFor microwave signals requires at least one antenna on or embedded in theobject and at least three other antennas at precisely known locations inthe frame of reference. The signals between the antenna on the objectand each of the three other antennas are converted to raw distancesbetween the respective antennas. These raw distances are measures of thelinear physical distance in three-dimensional space (that is, in theframe of reference) between the phase centers of the respectivetransmitting and receiving antennas. For example, signals may betransmitted from the object to the other antennas, where they areforwarded to receivers for analysis and conversion into raw distances.Measurements obtained from one transmitting antenna to additionalreceiving antennas should theoretically resolve to the same point.However, if the signal between a receiver-transmit antenna pair istemporarily compromised, a measurement for that pair may resolve to adifferent point.

According to one aspect of the invention, accurate three dimensionaltracking of an object is provided even when line of sight is obstructedby calculating raw distances between the object and some number ofreceiving antennas greater than three and associating confidencemeasurements to the respective raw distance measurements. During asuccessive approximation process, the confidence measurement is appliedto a difference calculation between the raw distance and a deriveddistance associated with an estimated position of the object. Theconfidence weight thus controls the impact that a particular rawdistance calculation has on the overall estimated position calculation.

The confidence weight can be used to reduce the impact of a measurementwith intermittent anomalies (either in the raw distance itself or incomponents that are used to derive the raw distance measurement) or ameasurement that is historically trending in an unexpected, divergentmanner. In existing technology, when signals between the object and thesensors in the frame of reference become compromised, the navigatedsurgery system is disabled, alarms are sounded, and the delivery of careto the patient is suspended until those signals and the tracking of theobject can be restored. Such discontinuity is both frustrating anddangerous.

In the present invention, multiple redundant antennas at precisely knownlocations in the frame of reference are used, and confidence weights areapplied to raw distances in order to mitigate the impact of factors thatmight compromise the signal from the object, including factors such asobstructions in the line of sight between a transmitting and receivingantenna. Moreover, since confidence weights are updated for every signaltransmitted between the antenna on the object and every receivingantenna, it is a self-correcting influence on position calculationswithout resulting discontinuity in service. Various embodiments of thisinvention will include four or more receivers to improve reliability andaccuracy; even if one or more receivers becomes partially or totallyobstructed for a period of time, the remaining receivers can be used forposition determination without the need to discontinue use of thesystem.

FIG. 4 illustrates a historical data store 450 that may be used by LOSmodule 17 to determine a confidence weight to associate with eachtransmit antenna/receiver pair. As will be described in more detailbelow, each transmit antenna may also transmit multiple frequencies, andthere may be a set of the data stores 450 for each frequency of thetransmit antenna/receiver pair.

The data store 450 includes a plurality of data stores including a rawdistance data store 452, a signal component data store 454 and aposition data store 456. The data stores store may be arranged asfirst-in first-out (FIFO) buffers that store information used in Mprevious position determinations. In one embodiment, M may be, forexample, five or six, but it will be recognized that the selection of aFIFO depth is a matter design choice. The raw distance data store 452stores the raw distance results for the transmit antenna/receiver pair.The signal component data store 454 stores various signal measurementsperformed by the receiver for the transmitted signal, including but notlimited to signal strength and phase angle. The position store 456stores the previously generated position of the object. It should benoted that although various data stores are shown by way of example, thepresent invention is not limited to the use of any particularcombination of historical values when generating the confidence weightbut rather it is envisioned that any data associated with a receivedsignal may be used to derive a confidence weight for a transmitantenna/receiver pair.

The confidence weight is determined by the confidence weightdetermination logic using any combination of data in the historical datastore. The confidence weight can be determined using both informationrelated to one transmit antenna/receiver pair, and also through thecomparison of the information with other transmit antenna/receiverpairs. In one embodiment, a confidence weight may be generated throughan analysis of a subset of historical data to determine the standarddeviation of the subset. In some embodiments the standard deviations maybe averaged, while in other embodiments the highest standard deviationmay be used. A confidence weight may be assigned to the raw distancemeasurement that is the inverse of the standard deviation of the subset.Thus if a particular result or component is noisy, the resultingconfidence weight will reduce the impact that such a result has in thedetermination of position. Other methods of evaluating the data anddetermining a confidence weight using statistical methods or othertechniques are considered equivalent hereto and the present invention isnot limited to any particular method of parsing the historical data todetermine a confidence weight.

Evaluating the historical data in this manner helps to identify a trendin receiver operation, or a divergence of a receiver from its trendingbehavior both at a signal component, distance measurement and positiondetermination granularity. Among the trends that can be discovered arethe rate of change of distance between successive measurements,deviation in distance as measured by signals of different frequencies,and relative noisiness of successive measurements. For example, if aparticular receiver detects rapid variations in the phase angle,suggesting that the object is moving, while other receivers detect nochange, then the confidence measure of the particular receiver should belowered. Also, if an intensity of a signal between a transmitantenna/receiver pair is substantially weaker than other pairs and/orsubstantially weaker than historical values of the pair, the confidenceweight is lowered.

In one embodiment, the position estimate may store both a historicalposition of the object as well as a position determination made withoutincorporating the information from the particular transmitantenna/receiver pair. If the two positions diverge, then the confidenceweight associated with the transmit antenna/receiver pair is lowered.

When calculating the three dimensional positions of objects, thesemeasures of confidence are applied as weighting factors for eachreceiver-transmit antenna pair. If a pair has full confidence, then itsdistance will be used with full weight to calculate location. Pairs withlower confidence will have proportionally less impact on the locationcalculation. The more receivers, the more data will be provided, therebyimproving the accuracy and reliability of the system.

FIG. 5 illustrates additional components that may be included in areceive circuit 300. A transmit circuit 222 provides an input RF ormicrowave signal 201 of the desired frequency to transmitter 205, whichin turn transmits that signal via transmit antenna 210. (Transmitantenna 210 corresponds to any of transmit antennas 26 a-26 d in FIG.1.) The signal 201 is also forwarded as a reference signal 221 toreceiver 300. Receiver 300 is coupled to a receive antenna 230 (whichcorresponds to any of antennas 25 a-25 f of FIG. 1) and includes a phasediscriminator 240, a recorded phase reference at the origin 250, adistance calculator 260, an historical data store 270, and processinglogic 271. The outputs of receiver 300 are a raw distance 280 and aconfidence weight 290. Input signal 201 is transmitted at periodicintervals by transmitter 205 and antenna 210 to receiving antenna 230.The output of receiving antenna 230 is amplified and sent to phasediscriminator 240.

Phase discriminator 240 determines the phase angle between the receivedsignal and reference signal 221. The result is digitized and subtractedfrom the stored phase reference at origin 250 to provide a phase change.This phase change represents the difference between the phase of thesignal received by this particular receive antenna 230 from thisparticular transmit antenna 210 with the object at its present locationand the phase reference determined for this particular transmit/receivepair at the origin. The digitized result is applied to geometricdistance calculator 260, which converts phase change into distance anduses historical data 270 to add the appropriate number of wholewavelengths. This sum is the raw distance 280 between the transmit andreceive antenna, in particular, between their phase centers. It will beappreciated that a distance, if calculated from the current phase anglealone could only determined modulo the wavelength of the transmittedfrequency. Therefore, in a practical implementation, distance calculator260 retains the raw distance from the previous interval and calculatesthe raw distance 280 of the present interval to be within one wavelengthof the previous distance.

It will be appreciated that there are many ways to calculate the rawdistance between the origin and the moving antenna. For example, insteadof subtracting the phase angle from the phase reference at the origin, acalculation may differentiate and then integrate the phase angle. Allsuch ways are within the scope of this invention.

The output of the digitized data from phase discriminator 240 is alsoapplied to historical data store 270, which retains the phaseinformation and other information from the previous positiondeterminations, including the data records illustrated in FIG. 4. Thehistorical data is used to calculate confidence weight 290 using thetechniques described above.

FIG. 6 is a diagram of a multi-receiver navigated medical environmentwhich will be used to describe how the confidence weights may be appliedto determine absolute position of the object by a method of successiveapproximation. FIG. 7 is a flowchart illustrating the successiveapproximation method. With regard to FIG. 6, at periodic intervals, eachreceiver (300 a-300 n) receives a signal from each transmit antenna 210(i.e., 26 a-26 d of FIG. 1). The receiver than determines a raw distanceand confidence weight corresponding to each transmit/receive antennapair (and potentially, as will be described below, for differentfrequencies of the transmit antenna/receiver pair). The raw distancesare compared by comparators 250 against estimated distances 321 derivedfrom estimated position 310 via model functions 320. The results of thecomparison are multiplied by the confidence weight of the receivers atmultipliers 296, and the results are combined into an offset that isforwarded to a Threshold Compare and Estimate Adjustment module 340,which adjusts the estimated position and forwards it to module 310. Asdescribed in FIG. 7, the estimated position is repeatedly adjusted untilthe offset is within a desired threshold, at which point the estimatedposition is deemed to be the actual position of the object and can beforwarded to the Navigated Surgery workstation 12 (FIG. 1).

FIG. 7 depicts a functional flow diagram of the method of successiveapproximation in a preferred embodiment. An initial estimated position432 (corresponding to 310 in FIG. 6) is determined. A Raw Distance(RD_(N)) and advantageously a confidence weight (CW_(N)) are determinedfor each transmit/receive antenna pair and are forwarded to thecomparison block 435 of FIG. 7 (corresponding to 340 of FIG. 6). Theloop of FIG. 7 is an iterative process that determines the quality ofthe estimated position of the object with respect to distances derivedfrom that estimated position and updates the estimated position toimprove that quality.

In one embodiment, information regarding a previous position may be usedto provide an initial value of the estimated position variable 432,although it is not a requirement. The estimated position is forwarded toa model function 434 (corresponding to 320 in FIG. 6) that derivesdistances DD_(N) between each transmit/receive antenna pair using amathematical formula. The derived distances are forwarded to aminimization process 435.

Raw distance and confidence weights associated with eachtransmit/receive antenna pair are also forwarded to the minimizationprocess 435. In a preferred embodiment, process 435 uses a standardLevenberg-Marquardt technique to speed the convergence of a series ofsuccessive estimated positions of the object within a reasonable numberof iterations to the actual position of the object.

Thus at step 436 an offset between derived and raw distances iscalculated using Equation 2 as follows:

$\begin{matrix}{{offset} = {\sum\limits_{N = 1}^{N = {TA}_{Num}}{{CW}_{N}*( {{RD}_{N} - {DD}_{N}} )^{2}}}} & ( {{eq}\mspace{14mu} 2} )\end{matrix}$

where CW_(N), RD_(N) and DD_(N) are respectively the confidence weight,raw distance and derived distances associated with the relationshipbetween the Nth transmit-receive antenna pair, and TA_(NUM) is the totalnumber of such receive-transmit antenna pairs. The offset is thus thesum of the squares of the weighted differences between the derived andraw distances.

The offset serves as a numerical indication of the quality of theestimated position. If the offset is near zero, then either all of theraw distances are very close to the derived (measured) distances, or thefew raw distances that are far from their corresponding deriveddistances are weighted so low as to have little impact on the position.Thus, a small offset value implies that estimated position of the objectis very near the actual position. If the offset is much larger thanzero, the estimated position of the object is correspondingly fartherfrom the actual position. At step 437 the offset is compared against apredetermined threshold based on the required precision of the positionof the moving object. If the offset is within the threshold, theposition determination is complete, and the calibrated receiver positionis stored at step 439. If the offset is not within the threshold, thenat step 438 the estimated position is adjusted and the process returnsto step 432, where the minimization process 435 is repeated with the newestimated positions until the offset is within the desired threshold.

It is appreciated that one method of adjusting the estimated position isto use Jacobian adjustment techniques to expedite determination of anestimated position, although other methods, such as random andincremental adjustment may be used and the present invention is notlimited to the use of any particular manner of adjustment. In oneembodiment, to improve the accuracy of calibrating each of the receivingantennas, a plurality of input RF or microwave frequencies mayadvantageously be used. This minimizes the effect of multipathdistortion and other interference.

It will be appreciated that although a particular process forcalibrating an object position has been described in FIGS. 7 and 6, thepresent invention is not limited to the use of any particular positiondetermination process or algorithm. The process of FIG. 7 may berepeated for each instrument in the navigated medical environment.

It will be appreciated that other embodiments within the scope of thisinvention may use other minimization criteria to determine the bestestimate of the position of the object from imperfectly receivedsignals.

FIG. 8 is a flow diagram illustrating exemplary steps in a process 900that may be performed by the LOS module to determine a confidenceweight. At step 902 the LOS module receives the raw distance and othersignal information for each transmit/receive antenna pair. At step 902the LOS module analyzes the received information in view of data in thehistorical data store and generates a confidence weight at step 906. Atstep 908 the LOS module forwards the confidence weight and raw distanceinformation to a positioning module 19.

It should be understood that the confidence weight of this invention maybe used to validate the reading of any device, and that the direction oftransmission between a fixed and moving antenna is irrelevant. That is,the method works equally well if a) the transmitting antennas areattached to the object and the receiving antennas are part of the frameof reference, b) the receiving antennas are attached to the object andthe transmitting antennas are part of the frame of reference, and c)some combination of the transmitting and receiving antennas are attachedto one or more moving objects and the remaining are the part of theframe of reference.

Accordingly, a system and method for ensuring the accuracy of positionalinformation in an environment where line of sight obstruction and otherinterference is present has been shown and described. Maintaining ahistory of receiver behavior and weighting the confidence given to thereceiver measurements based on past behavior minimizes the impact ofreceiver anomalies, blockages in the line of sight between atransmitting antenna and a receiving one, poor signal strength, or otherfactors. Providing a multiplicity of receivers and using confidenceweights to control the use of the received data in positiondeterminations increases the reliability and accuracy in a navigatedmedical environment by allowing self-correction to reduce disruptions toservice.

Antenna Calibration

In order to accurately track the positions of objects using phasedifferences or time differences of arrival of RF or microwave signals,it is crucial that the precise locations of the antennas in the frame ofreference be known to the desired degree of precision. It is alsocrucial that the precise locations of the antennas on each movableobject be known with respect to an internal coordinate system of thatobject, also to the desired degree of precision. For example, innavigated medical procedures this precision is in the range of 0.5 mm,and therefore, it is necessary to know the location of each antenna witha precision of at least 0.25 mm, so that the distance between them canbe known to the nearest 0.5 mm.

However it is often difficult to determine any antenna position to thisdegree of precision. For example, in an application of tracking surgicalinstruments, the receiving antenna array may be up to 2 meters indiameter and may be mounted on a movable cart. It is highly impracticalfor a surgical technician to measure or control the physical placementof the cart to a precision of 0.5 mm or better. Moreover, it isnecessary to know the location of not just any point on an antenna butrather its phase center. In one embodiment, the antennas on a movingobject are implemented as printed circuit elements approximately 12 mmlong and 6 mm wide. Locating the phase center of such an antenna towithin 0.5 mm is also highly impractical. In some antennas, the phasecenter may vary with the frequency being transmitted, and the variancemay be greater than the required precision for tracking an object. Inthese cases, the position of the phase center must be known as afunction of signal frequency.

In the present invention, a priori knowledge of the locations of thephase centers of the antennas in the frame of reference is not required.Instead, these locations are determined by a system calibration processprior to the start of each navigated procedure. In one embodiment, themethod may use a precisely manufactured calibration tool containing aplurality of transmit antennas with known geometry and known phasecenters. One exemplary embodiment of such a calibration tool is theassembly of FIGS. 2A and 2B.

In another embodiment, a calibration device comprises a single antennamounted on a precision motion control machine so that the antenna can bemoved to different locations during the system calibration process.Commercially available motion control machines suitable for this purposehave precisions in the range of tenths or hundredths of a millimeter orbetter.

The method of determining the locations of the antennas of a frame ofreference is similar to that of tracking moving objects, but with afundamental difference—there is no “phase reference at the origin.” Thatis, there is no a priori known phase angle with respect to which thephase of a particular signal can be compared. Therefore, it is notpossible to determine precisely the raw distance between an antenna onthe calibration device and an antenna in the frame of reference. Sincethe calculations of Equation 2 and FIG. 7 depend upon raw distances,they break down during system calibration.

Consider first a calibration device with a single antenna and a motioncontrol machine. A diagram of an example is depicted in FIG. 9. Transmitcircuitry 222 is coupled to calibration assembly 500, which contains amovable platform 520 on which is mounted transmit antenna 510. Signalgenerator 201 is coupled to transmitter 205, which transmits signal 210through transmit antenna 510. The movable platform is capable of beingmoved to a plurality of points, all of whose locations inthree-dimensional space are known to a high degree of precision. Let asignal be transmitted from each of points P₁, P₂, P₃, and P₄ insuccession to receive antenna 530, which is coupled to receiver assembly540. Also coupled to receiver circuitry 540 is reference signal 221 fromtransmit circuitry 222. Receiver circuitry 540 includes phasediscriminator 550, which measures the phase angle between a signalreceived by antenna 530 and reference signal 221.

It will be appreciated that when receiver antenna 530 and calibrationassembly 500 are both fixed in the frame of reference, the only changeof phase detected by phase discriminator will be due to the motion ofplatform 520. It will also be appreciated that distances D₁, D₂, D₃, andD₄ between antenna 530 and points P₁, P₂, P₃, and P₄, respectively, willnot be known within the required degree of precision.

However, their pairwise differences can be determined from the measuredphase differences. Let φ₁, φ₂, φ₃, and φ₄ be the phase differencesbetween reference signal 221 and the transmitted signal 210 from pointsP₁, P₂, P₃, and P₄, respectively, to receive antenna 530. Since thesephase differences are known by measurement, the pairwise differencesΔ₁₂, Δ₁₃, Δ₁₄, Δ₁₁, Δ₂₃, Δ₂₄, and Δ₃₄ between the distances D₁, D₂, D₃,and D₄ can be determined from the equations

$\begin{matrix}{\Delta_{12} = {( {D_{1} - D_{2}} ) = {\frac{c}{2\pi \; f} \times ( {\varphi_{1} - \varphi_{2}} )}}} & ( {{eq}\mspace{14mu} 3} ) \\{\Delta_{13} = {( {D_{1} - D_{3}} ) = {\frac{c}{2\pi \; f} \times ( {\varphi_{1} - \varphi_{3}} )}}} & ( {{eq}\mspace{14mu} 4} ) \\{\Delta_{14} = {( {D_{1} - D_{4}} ) = {\frac{c}{2\pi \; f} \times ( {\varphi_{1} - \varphi_{4}} )}}} & ( {{eq}\mspace{14mu} 5} ) \\{\Delta_{23} = {( {D_{2} - D_{3}} ) = {\frac{c}{2\pi \; f} \times ( {\varphi_{2} - \varphi_{3}} )}}} & ( {{eq}\mspace{14mu} 6} ) \\{\Delta_{24} = {( {D_{2} - D_{4}} ) = {\frac{c}{2\pi \; f} \times ( {\varphi_{2} - \varphi_{4}} )}}} & ( {{eq}\mspace{14mu} 7} ) \\{\Delta_{34} = {( {D_{3} - D_{4}} ) = {\frac{c}{2\pi \; f} \times ( {\varphi_{3} - \varphi_{4}} )}}} & ( {{eq}\mspace{14mu} 8} )\end{matrix}$

where c is the speed of light in air, f is the frequency oftransmission, and the constants k_(ij) represents the whole number ofwavelengths to add to the difference in phases between points i and j.Each constant k_(ij) can be determined by inspection, by simplemeasurement (e.g., a tape measure), by continuous tracking in the sameway raw distances are determined when tracking an object, or by themethod of short and long wavelengths described below.

FIG. 10 is a flowchart describing a method of successive approximationto determine the position of antenna 530 relative to calibration device500. An initial, imprecise estimate of the position is made by simplemeasurement, for example, by a tape measure. This is applied toestimated position 560. A model function 562 then performs a geometriccalculation to determine derived distances DD₁, DD₂, DD₃, and DD₄between the phase center of receive antenna 530 at its estimatedposition and the phase center of transmit antenna 510 actual positionwhen motion platform 520 is at points P₁, P₂, P₃, and P₄, respectively.In order for the model function to determine the derived distance, itmust know the exact geometry of the calibration device and the precisepositions of antenna 510 at which phase angle measurements are taken.

Next, minimization unit 564 computes an offset 566 according to thefollowing equation.

$\begin{matrix}{{offset} = {\sum\limits_{i = 1}^{4}{\sum\limits_{j = i}^{4}( {\Delta_{ij} - ( {{DD}_{i} - {DD}_{j}} )} )^{2}}}} & ( {{eq}\mspace{14mu} 9} )\end{matrix}$

where N is the number of discrete points at which phase anglemeasurements are made during the calibration. In step 568, offset 566 iscompared to a predetermined threshold based on the required degree ofprecision. If the offset is within the threshold, then the estimatedposition of the antenna 560 becomes the actual position of the antenna572. Otherwise, the estimated position is adjusted in step 570, and thecomputation is repeated.

By this means, the phase center of the antenna 530 is determined withrespect to the coordinate system of the calibration system. The methodof successive approximation of FIG. 10 is repeated for each antennarequiring calibration.

Once a set of antennas has been calibrated with respect to somecoordinate system, that set can be used to calibrate other antennas. Forexample, a precision manufactured calibration device that includes aplurality of antennas in a predetermined array could be calibrated atthe factory by the methods of FIGS. 9 and 10. The positions the phasecenters of its antennas would thus be known within the requiredprecision. Moreover, any phase differences that may exist among theantennas of the set can be discovered and recorded at the same time. Theknowledge of the geometry of the calibration device and the precisepositions of the phase centers of its antennas is applied to the modelfunction 562 in order to calculate derived distances DD_(i) from theestimated position of an antenna being calibrated. The knowledge ofphase differences of the antennas, if any, is applied Equations 3-8 tocorrect the measured phase differences.

FIG. 11 depicts a precision calibration tool 400 that, can be used tocarry out the system calibration of the antennas in the frame ofreference prior to a navigated medical procedure. During calibrationprocess, a signal 210 is transmitted through multiplexer 206 througheach of transmit antennas 410 a-410 d in turn to antenna 230. Phaseangles φ₁, φ₂, φ₃, and φ₄ representing the difference of the receivedsignal and reference signal 221 are recorded. Equations 3-8 are thenapplied to obtain the differences in distances from the respectivecalibration antennas 410 a-410 d to antenna 230. The method ofsuccessive approximation of FIG. 10 is applied to determine the positionof antenna 230 with respect to the calibration device to the requiredprecision. The same steps are repeated for each antenna in the frame ofreference. Finally, the coordinate system of calibration device 400becomes the coordinate system of the frame of reference. That is, theorigin of the coordinate system of calibration system 400 becomes theorigin of the frame of reference, and the x-, y-, and z-axes of thecalibration system become the x-, y-, and z-axes of the frame ofreference. The calibration device can then be removed or set aside.

In a similar manner, the antennas of any object or instrument can becalibrated at the time of manufacture by the same method, but withrespect to the internal coordinate system of the object or instrument.It will also be appreciated that although Equation 9 specifies aminimization of the sum of squares, a minimization of some otherfunction of the D and the derived distances is also within the scope ofthis invention.

It will be appreciated that one precision calibration device with amovable platform can be used to calibrate a family of other calibrationdevices and instruments, and that these can be used to calibrate otherdevices and sets of antennas, and so on. It will also be appreciatedthat the same calibrations can be carried out, using the same equations,when the receive antenna is mounted on the calibration device and thetransmit antennas are the ones to be calibrated.

It will be appreciated that although a particular process forcalibrating receive antenna position has been described in FIGS. 9-11,the present invention is not limited to the use of any particularposition determination process. Rather it should be appreciated that theconcept of using a calibrated tool having fixed geometry and phasecenter to determine distances to an antenna can be used in a variety ofnavigated medical environments.

The process of FIG. 10 may be repeated for each receive antenna in thenavigated medical environment. The calibrated positions of the receiverstogether form a frame of reference from which subsequent positiondeterminations may be made for tracked objects in the navigated medicalenvironment.

Accordingly, a system and method for determining a precise location of areceiver assembly for calibrating a navigated surgery system has beenshown and described. Periodic transmissions from multiple antennae on acalibrated tool are received by a receiver assembly, and raw distancesto the transmitting tool are calculated. A minimization algorithm isapplied to determine precise location of the receivers.

Multipath

As discussed briefly above, a multipath component 18 in the computerfacilitates precise distance measurement in the presence of multipathinterference by sequential adjustment of the frequency of thetransmitted signal 27 and appropriate filtering of received signals.

In wireless telecommunications, a multipath effect is interference in areceived signal caused by the propagation of a transmitted signal alongmultiple paths to its destination. Reflections and refractions of thetransmitted signal as it encounters obstacles before it reaches thereceiver causes the transmitted signal to reach the destination viamultiple paths. Each path taken by a transmitted signal will have adifferent length and therefore a different arrival time or, phase at thereceiver. Each specific frequency of a radio or microwave signalbroadcast in a confined space will have a unique three dimensionalpattern of positive and negative interference between the differentpaths. This interference pattern is referred to as a multipath effect.

In a navigated surgery environment, distances may be discerned bycomparing the phase of a received signal against a phase of a referencesignal as described above. However, multipath interference can degradethe received signal and result in inaccurate phase detection andconcomitantly reduce the precision with which the position of anavigated instrument can be discerned. For example, FIG. 12 is a graph1000 illustrating the movement of a transmit antenna over time atconstant velocity. The Y axis represents a range, in mm, of the transmitantenna from a receiver while the X axis is a time interval. Line 1002represents the actual position of the transmit antenna over time, whileline 1004 illustrates an apparent measured position using a receivedsignal having multipath effects. It can be seen that the error betweenthe apparent measured position and the actual position varies over timewith the position of the transmit antenna.

According to one aspect of the invention it is realized that a distancemeasurement of increased accuracy can be obtained by reducing the effectof multipath interference through sequential adjustment of the transmitfrequency of the transmitted signal. In one embodiment, a signal istransmitted as a repeating sequence of unique frequencies from eachtransmitter, with each frequency of the sequence differing by a smallamount so that the wavelengths of the transmitted signals differ bysmall fractions. This is well known in the electronic art as frequencyhopping spread spectrum. A distance calculation is then done at areceiver for each frequency, and the calculated distances are thenfiltered to derive a “best” distance from the object to that receiver.The sequence of frequencies is retransmitted at rapid intervals so thatthe object can be tracked as it moves through three-dimensional space.Switching frequencies at frequent intervals in this manner increases theaccuracy of distance calculations by limiting the impact of multipathinterference for each frequency.

FIG. 13 illustrates a plurality of sequences of frequencies transmittedby one transmitter over a period of time. The horizontal axis 101denotes time, and the vertical axis 102 denotes frequency. A sequence ofunique frequencies is transmitted during a sequential time interval 130.Frequency intervals 120 denote the length of time that each frequency istransmitted. It will be appreciated that in any practical embodiment,the length of each frequency interval 120 should be long enough for thetransmitter to stabilize on that frequency so that a stable wave can beset up in the region of the apparatus. In particular, when a transmitterswitches from one frequency to the next, there will be a short period offrequency instability 140 before a stable frequency is attained.

It should be noted that although an increasing step frequency sequenceis shown in FIG. 13 the present invention is not limited to such afrequency pattern; rather any pattern of unique frequencies may betransmitted over the sequence and the present invention is not limitedto any particular pattern of unique frequencies.

As described with regard to FIG. 1, in one embodiment transmit circuitry22 includes a switch that sequentially transmits the signal out of eachof the four antennas of the transmit antenna assembly during thefrequency interval 120. Thus during an example sequential time interval130, the signal 27 will be transmitted at 32 unique frequenciessequentially across each of the four antenna of a transmit assembly. Thereference signal 21 also sequences through the same frequencies. Thephase angle between a reference signal and the signal detected by onereceiver is converted into a distance to that receiver using theknowledge of the distances determined from the previous fewtransmissions of the same frequency. When the distances are thuslydetermined for all of the frequencies of a sequence, they will varybecause of the different effects of multipath distortion on thedifferent frequencies. A filter is used to select the “best” estimate ofthe distance.

FIG. 14 shows an embodiment of circuitry which may be associated witheach receiver (and located either at the receiver or as part of theMultipath component of the computer 14) to calculate a raw distancebetween the respective receiver and a transmit antenna using themultiple frequency phase offset information obtained as described above.For each of the N frequencies of one sequence, a phase angle difference40 between the received signal and the reference signal for thefrequency is obtained for the receiver 20 (FIG. 1). FIFO storage units50 store a set of previously calculated distances for the frequency forthe receiver from a small set of previous sequences, where one FIFO isassigned to each frequency of the sequence. Distance calculators 55estimate the distance to the receiver based on the particular frequency,the phase angle 40, and the previously known distances in FIFO 50.

The outputs of the distance calculators 55 are coupled both to therespective FIFOs 50 and to a filter 60. The filter 60 evaluates each ofthe received distances and derives a distance by applying a statisticalfilter to the collection of derived distances. The statistical filtermay be, for example, a mean or median filter. Experimentation has shownthat both mean and median filters provide highly accurate estimates ofthe actual distance, provided that a previous reference point isestablished to start the process. However, it should be noted that thereare a variety of other filtering methods that can be used to select a‘best’ distance result. These methods include but are not limited toboth statistical filtering methods (including but not limited to mean,median, standard deviation measurements and combinations thereof) aswell as predictive or heuristic filtering (for example, anticipating adistance delta based on prior data) and the like.

In one embodiment of the invention a confidence weight such as thatdescribed above with regard to FIGS. 4-8 may advantageously be assignedto either each the calculated distances from distance calculator 55 oralternatively to the filtered result 65 to compensate for interferenceat the various frequencies.

FIG. 15 illustrates a graph of distances determined by a transmitantenna moving away from a receiving antenna at a fixed speed. Each line(other than line 70) represents the apparent distances between an objectand an antenna as determined by an individual frequency. As can be seenin the plot, these frequency-determined distances fluctuate around anactual distance. Line 70 represents the distance calculated by applyingthe statistical filter to the derived distances obtained using the stepfrequencies of FIG. 13.

For example, with frequencies in the range 5.7-5.85 GHz, multipathdistortion can cause the apparent distances determined for one receiverfrom each frequency to vary as much as several millimeters from theactual distance as measured with a precise measuring tape. However, whenthe distances are filtered among all of the frequencies of the sequence,the result (70) is accurate within a tolerance of less than onemillimeter.

FIG. 16 illustrates flow diagrams of exemplary steps that may beperformed during a transmit process 1400 and receive process 1420 tominimize the impact of multi path interference according to the presentinvention. At step 1402 a step counting variable N is set to 0. At step1403, a signal generator generates a signal having a frequency equal tothe base frequency+the step frequency increment*N. The signal istransmitted for the step interval time. As mentioned above, the stepinterval time may be sufficient to allow each of a number of transmitantennas 26 a-26 d to transmit a stable signal to the receiver.

At step 1404 it is determined whether the number of step frequencies ofa sequence has been transmitted. If not, at step 1405 the variable N isincremented by 1, and the process returns to step 1403. If at step 1404it is determined that all frequencies in the sequence have beentransmitted, then the process continues to step 1406, where a sequencecount is incremented. At step 1407 it is determined whether the numberof sequences per interval has been processed. If not the process returnsto step 1402. If the all sequences in the interval have beentransmitted, then the transmit process is complete and a position of theinstrument can be determined.

While logic associated with the transmitter is executing process 1400the receiver is executing process 1420. At step 1422 the receivercontinuously receives signals from the transmitter, a total ofN*TA_(NUM) (where TA_(NUM) is equal to the number of antennas pertransmit antenna assembly). At step 1424 the receiver determines thephase difference between the received signals and associated referencesignals for each of the frequencies in the sequence. At step 1426 adistance is derived for each of the frequencies in the sequence. At step1427 a confidence weight may optionally be applied to the deriveddistance to reduce the impact of derived distances that displayanomalies. At step 1428 the derived distances are filtered using astatistical filter to identify a ‘best’ distance between the receiverand transmit antenna. This distance is passed to positioning logic toidentify a three dimensional position of the instrument, for exampleusing an iterative process such as that described above with regard toFIG. 7.

It will be appreciated that other embodiments of this method candetermine the distance between a transmit antenna and a receiver in thepresence of multipath distortion. In particular, many embodimentsimplement the method in software, and some embodiments integrate thedistance derivation with other calculations and the feedback of otherinformation to the FIFOs 50.

It will also be appreciated that in a system with multiple transmitantenna assemblies, the intervals 120 from each transmit antennaassembly can be interleaved, so that multiple objects can be tracked atthe same time.

In addition, although the description has described the process from theperspective of a transmit assembly associated with an object forwardinga signal to a receive antenna in a frame of reference, it is recognizedthat a similar method may be used to locate the position of a receiveantenna for example by transmitting from a calibration tool. Inaddition, it is appreciated that a navigated surgery system that usesmounted transceivers to track an object that includes only a receivingantenna may advantageously benefit from application of the multipathinterference reduction methods of the present invention. Such anembodiment will be described later herein.

Accordingly a method and system for precisely determining a distancebetween a wireless transmit antenna and receiver in the presence ofmultipath interference has been shown and described. Varying thefrequency of the transmission among a sequence of available frequenciesover a time interval minimizes the impact of multipath effects in thereceived signals.

Absolute Positioning

Although the above disclosure has described the transmission of a singlesignal, albeit at varying frequencies, according to one aspect of theinvention it is realized that when using a method for determining theposition of an object with embedded transmit antennas, phasediscrimination has practical limitations in precision of about onedegree of difference in phase angles. This means that the achievableresolution of the position of an object will be limited to a precisionof about 1/360 of a wavelength.

Therefore, to achieve high resolution, shorter wavelengths—i.e., higherfrequency signals—must be used. However since the value of phasedifference repeats with every wavelength of separation between transmitantenna and receiver, shorter wavelengths also lead to more positions ofambiguity within a given region of space.

FIG. 17 is a graph provided to illustrate the ambiguity that can arisewhen using shorter wavelengths. A first receiver 1500 detects a phaseangle φ₁ with respect to the reference signal. This can place thetransmit antenna at any of the distances d₁₁, d₁₂, d₁₃, d₁₄, etc., fromreceiver 1500. A second receiver 2000 detects a phase angle φ₂ withrespect to the reference signal. This can place the transmit antenna atany of the distances d₂₁, d₂₂, d₂₃, d₂₄, etc., from receiver 2000. Itcan be seen that there are many possible positions for the transmitantenna for these two phase angles. It will be appreciated that evenwith a third receiver there will be many possible positions of thetransmit antenna in three-dimensional space for a given set of phaseangles. Additional receivers will narrow down the number ofpossibilities but not unambiguously identify the actual position of thetransmit antenna.

The above problem is compounded in practical environments in which atransmit assembly may “drop out of sight” of a receiver for a shorttime, perhaps due to a person or object moving in the way or tointerference generated by equipment in the vicinity.

However, according to one aspect of the invention it is realized that ifit is possible to simultaneously transmit two RF signals ofsignificantly different wavelengths from the same transmitting antenna,then the ambiguity can be reduced to the certainty inherent in thelonger wave length, while the resolution of the position can bemaintained by the precision of the shorter wavelength.

The simultaneous transmission of two frequencies is illustrated in FIG.18, which shows the case of only one receiver 1500. In the example ofFIG. 18, with appropriate filtering receiver 1500 may detect two signalstransmitted by the transmit antenna and therefore two phase angles withrespect to the previously established reference. Phase angle φrepresents the angle detected for the high frequency (shorterwavelength) signal, and phase and θ represents the phase angle detectedfor the lower frequency (longer wavelength) signal. Phase angle φ makesit possible to position the transmit antenna at a multiplicity ofdistances d_(φ1), d_(φ2), d_(φ3), d_(φ4), etc., from receiver 1500. Bycontrast, phase angle θ makes it possible to position the transmitantenna at only two distances, d_(θ1) or d_(θ2) from the receiver 1500.However, the coarse precision of bis sufficient to identify which of thepossible precise distances indicated by 0 represents the actual positionof the object.

In the present invention, the transmit antenna transmits two frequenciesat the same time, one with a sufficiently long wavelength tounambiguously determine the position of the object within the region ofinterest but to only a coarse degree of precision, and the other with asufficiently short wavelength to determine the position of the object tothe desired degree of position.

In one embodiment—for example, one suitable for a navigated medicalenvironment—the two frequencies are approximately 100 MHz and 5.8 GHz,respectively. The table below shows two frequencies, 100 MHz and 5.868GHz, along with their corresponding wavelengths. At 100 MHz, it ispossible to resolve the position of an object to only a precision ofabout 8 mm, even using a highly accurate phase discriminator resolvableto one degree. By contrast, in the 5.8 GHz range, it is possible toresolve the position of an object to better than 1 mm, even with a phasediscriminator capable of resolving to only within 5 degrees.

TABLE I FRE- QUEN- PHASE SINGLE CY WAVE- DISCRIM- FREQUENCY (MHz) LENGTHINATOR RESOLUTION AMBIGUITY 100 2997.92 1 8.33 1 5868 51.09 5 0.71 39

However, the 100 MHz signal can correctly determine the position of theobject to a unique position within a cube that is 2 meters on a side. Bycontrast, there are about 39 different distances within a 2-meter cubethat correspond to exactly the same phase difference for a signal of5.868 GHz.

FIG. 19 illustrates such an embodiment. Input RF or microwave signals1111 and 1112 are of lower and higher frequencies, respectively. Theseare applied to mixer 1120 and also to phase discriminators 1161 and1162, where they act as reference signals. The two input RF signals arecombined in mixer 1130 and applied to transmitting antenna 1135, fortransmission to receiving antenna 1140. Receiving antenna 1140 iscoupled to receiver 1141, which receives and amplifies the combinedsignal. This signal is then passed to filters 1151 and 1152 to extractthe low and high frequency components, respectively. These componentsignals are then passed to phase discriminators 1161 and 1162,respectively, to derive phase differences 1171 and 1171 between the tworeceived frequencies and their reference frequencies. Raw distances arecalculated for each of these phase differences, and they are eachincluded in a position determination process such as that illustrated inFIG. 7.

In practical situations, it is often difficult to transmit signals ofradically different frequencies from the same antenna efficiently.Therefore, according to another aspect of the present invention, arefinement of the above method is provided to transmit two simultaneoussignals of nearly the same wavelength and to derive the lower frequencysignal from them. For example, if the two frequencies are 5.7 and 5.8GHz and the phase relationship between them is fixed, then a 100 MHzsignal can be derived from them, also with a fixed phase relationship.

FIG. 20 illustrates a preferred embodiment. An input 5.75 GHz signal 113and a low frequency 50 MHz signal 1114 are coupled to mixer and filter1121. The mixing of these two frequencies produce two sidebandsfrequencies, 5.7 GHz signal 1125 and 5.8 GHz signal 1126. Mixer andfilter 1121 also filters out the original 5.75 GHz and 50 MHz signalsleaving only the two sideband frequencies. The phase relationshipbetween these sidebands is defined by the original 50 MHz signal. As aresult, because the same source oscillator is used to create both of thesignals that are input to the mixer, the resulting signals are phaselocked and do not drift. As a result, the phase relationship between thesignals is constant and permits reliable synthesizing of a 100 MHzsignal whose phase angle can be used to determine a position within thenecessary precision. In one embodiment the signal is referred to as a‘beat’ signal, and is obtained by taking the difference between the 5.7GHz and 5.8 GHz signals. It will be appreciated that if the 5.7 GHz and5.8 GHz signals are not kept in fixed phase relationship, the 100 MHzdifference between them which provides the basis for the beat signal isunusable for distance determination based on phase angles because thephase reference at the origin of the 100 MHz signal would not beconstant.

Signals 1125 and 1126 are combined and sent to transmit antenna 1135. Inaddition they are sent mixer 1122, to synthesize a 100 MHz referencebeat signal 1127 representing the difference between 5.7 GHz and 5.8 GHz127 for reference to the low frequency phase discriminator 1161. Signal1125 is also sent as reference to the high frequency phase discriminator1162.

The transmit antenna transmits the combined 5.7 and 5.8 GHz signal toreceiving antenna 1140 and receiver 1141. The combined received signalis then coupled to filters 1152 and 1153 to extract the component 5.7GHz and 5.8 GHz signals. The 5.7 GHz signal is sent to the highfrequency phase discriminator 162, to obtain the phase differences 1172from the reference signals 1125.

In addition, the outputs of 5.7 GHz filter 153 and 5.8 GHz filter 152are sent to mixer 1123 to synthesize a so-called ‘virtual’ 100 MHz beatsignal 1128 representing the difference between 5.7 GHz and 5.8 GHz. Therespective reference and virtual beat signals 1127 and 1128 are appliedto phase discriminator 1161 to obtain the phase angle 1171 of the 100MHz synthesized signals.

With such an arrangement, a low frequency signal is virtuallytransmitted between a transmit antenna and a receiver by transmittingtwo high frequency signal and determining the difference between thehigh frequency signals at the transmitter and at the receiver. Such anarrangement removes the need to provide high and low frequency antennasin the transmit antenna assembly. In addition, because the 100 MHZsignals are directly synthesized from the transmitted and receivedsignal pairs, they retain the phase coherence relationship that enablesthem to be used to calculate position. This phase difference can be usedto position an object within one wavelength of a 5.7 GHz signal. Ittherefore makes it possible to reconstruct the position of an objectthat is temporarily obscured from some or all of the receiving antennas1140 without having to recalibrate it. Since the actual transmittedsignals of 5.7 GHz and 5.8 GHz are so close in wavelength, a single setof transmit and receive antennas can used to efficiently convey bothcourse and fine position information.

It will be appreciated that there will be many other embodiments withinthe scope of this invention, some using analog methods and others usingdigital methods. In some embodiments, no low-frequency signal may beactually synthesized. Instead, the relative phases of the twohigh-frequency signals are used to determine a “virtual” phase angle forthe low-frequency signal, both at calibration time and during eachmeasurement of the changes in phase differences. All variations of theseembodiments are within the scope of this invention.

Exemplary Embodiment

Thus various aspects of the present invention have been shown anddescribed, each of which has stand alone utility in a navigated medicalenvironment. As described above, receiver calibration is crucial toenabling precise object tracking and the method and system describedwith regards to FIGS. 9-11 facilitates calibration of a reference frameprior to each navigated procedure. The concept and application ofconfidence weights can be applied to distance calculations to mitigatethe effects of interference and increase the tolerance of the navigatedmedical system through real time, intelligent analysis of signal anddistance information within and across the receiver framework.Multi-path interference is minimized through the transmission of asignal having a pattern of unique frequencies, storage of priordistances to resolve to appropriate wavelengths and filtering of theresults to ensure that the ‘best’ result is identified. In addition, itis realized that transmitting a signal using multiple frequencies canprovide increased resolution and accuracy.

In an exemplary embodiment, a 5.7 and 5.8 GHz signal are generated usingthe same oscillator, as shown in FIG. 6, and mixed to provide a 100 MHzsignal. The frequency of the 5.7 GHz signal is varied in a range over asequence interval by transmitting a pattern of unique frequencies withinthe range to the receiving device. Each receiver receives the signalpattern for each frequency step and calculates an estimated distance forthe frequency step using the methods described with regard to FIG. 14.The distance calculation and signal information may be used to determinea confidence weight to assign to the distance, either before or afterfiltering. The resulting distances are forwarded to a positioningalgorithm, which uses information from the 100 Mhz wavelength to resolveto a wavelength and a minimization process such as that in FIG. 7 toresolve to a smaller granularity. Preferred embodiments of the inventionadvantageously incorporate the confidence weight concepts whendetermining distances in the presence of multipath interference, asdescribed with regards to FIGS. 12-16. Multi-path interference andconfidence weight calculations can further be used to improve resultswhen using the absolute positioning methods and systems of FIGS. 16-20.With such an arrangement a navigated medical system with increasedaccuracy and reliability is provided.

It should be noted that although the above description of confidenceweights, multi-path and absolute positioning have been has directedtowards an embodiment where the object to be tracked is an instrument oranatomical marker, it is not required that the tracked object be thetransmitting device and that the tracking object be a receiving device.It is envisioned that aspects of the invention may be readily adapted toan environment where a reference frame comprises transceivers whichtransmit to the object to be tracked, and distance and positioncalculations are made from that perspective. Thus the present inventionis not limited to any particular transmission direction.

Having described various embodiments of the invention, it will beappreciated that many of the functions described above may beimplemented as computer programs that can be delivered to a computer inmany forms; including, but not limited to: (a) information permanentlystored on non-writable storage media (e.g. read only memory deviceswithin a computer such as ROM or CD-ROM disks readable by a computer I/Oattachment); (b) information alterably stored on writable storage media(e.g. floppy disks and hard drives); or (c) information conveyed to acomputer through communication media for example using basebandsignaling or broadband signaling techniques, including carrier wavesignaling techniques, such as over computer or telephone networks via amodem

The above description and figures have included various process stepsand components that are illustrative of operations that are performed bythe present invention. However, although certain components and stepshave been described, it is understood that the descriptions arerepresentative only, other functional delineations or additional stepsand components can be added by one of skill in the art, and thus thepresent invention should not be limited to the specific embodimentsdisclosed. In addition it is understood that the variousrepresentational elements may be implemented in hardware, softwarerunning on a computer, or a combination thereof.

While the invention is described through the above exemplaryembodiments, it will be understood by those of ordinary skill in the artthat modification to and variation of the illustrated embodiments may bemade without departing from the inventive concepts herein disclosed.Accordingly, the invention should not be viewed as limited except by thescope and spirit of the appended claims.

1. A method for determining a position of an object with high resolutionover a large area includes the steps of: transmitting a signal betweenthe object and an antenna, the signal having a long wavelength componentand a short wavelength component; deriving coarse distance informationfrom the long wavelength component of the signal and deriving finedistance information from the short wavelength component of the signal;and determining the position of the object using the coarse distanceinformation and fine distance information.
 2. The method of claim 1further including the steps of: receiving the signal, the receivedsignal comprising a received long wavelength component and a receivedshort wavelength component; deriving the fine distance information usinga first phase difference between a short wavelength component of areference signal and the received short wavelength component; andderiving the coarse distance information using a second phase differencebetween a long wavelength component of the reference signal and thereceived long wavelength component.
 3. The method of claim 1 wherein thesignal is transmitted by a transmitter coupled to the object andreceived by the antenna.
 4. The method of claim 1 wherein the signal istransmitted by the antenna and received by the object.
 5. A method fordetermining a position of an object with high resolution over a largearea includes the steps of: transmitting a signal between the object andan antenna, the signal comprising two components differing in frequencyby a desired amount; determining a coarse distance between the objectand the antenna in response to a difference between the two componentsof the signal and a fine distance between the object and the antennausing at least one of the two components of the signal; and determininga position of the object in response to the coarse distance and the finedistance.
 6. The method of claim 5 further including the steps of:determining the coarse distance between the object and the antenna bycomparing a phase difference between the two components with a phase ofa first reference signal; and determining the fine distance between theobject and the antenna by comparing a phase of at least one of the twocomponents of the signal to a phase of a second reference signal.
 7. Themethod of claim 5 wherein the two components have a fixed phaserelationship with each other.
 8. The method of claim 5 in which a beatsignal is derived by subtracting the two components of the signal and inwhich the coarse difference is determined from the phase angle of thebeat signal.
 9. The method of claim 8 further including the steps of:receiving the signal, the received signal comprising two received signalcomponents; deriving the fine distance in response to a first phasedifference between at least one of the received signal components and acorresponding component of a reference signal associated with thesignal; mixing the two received components to provide a virtual beatsignal; deriving the coarse distance in response to a second phasedifference between the beat signal and the virtual beat signal.
 10. Asystem for determining a position of an object with high resolution overa large area comprising: transmit circuitry for generating a signal fortransmission between the object and an antenna, the signal having a longwavelength component and a short wavelength component; a computerreadable medium having program code stored thereon, the program codeoperable when executed by a processor of the system to: derive coarsedistance information from the long wavelength component of the signaland deriving fine distance information from the short wavelengthcomponent of the signal; and determine the position of the object usingthe coarse distance information and fine distance information.
 11. Thesystem of claim 10 further comprising: receiver circuitry for receivingthe signal, the received signal comprising a received long wavelengthcomponent and a received short wavelength component; a first phasediscriminator for determining a first phase difference between a shortwavelength component of a reference signal and the received shortwavelength component; a second phase discriminator for determining asecond phase difference between a long wavelength component of thereference signal and the received long wavelength component; and whereinthe program code includes logic for deriving the fine distanceinformation using the first phase difference and deriving the coarsedistance information using the second phase difference.
 12. A system fordetermining a position of an object with high resolution over a largearea comprising: a transmitter for transmitting a signal between theobject and an antenna, the signal comprising two components differing infrequency by a desired amount; program code stored on a computerreadable medium of the system and operable when executed by a processorof the system to: determine a coarse distance between the object and theantenna in response to a difference between the two components of thesignal and a fine distance between the object and the antenna using atleast one of the two components of the signal; and determine a positionof the object in response to the coarse distance and the fine distance.13. The system of claim 12 wherein the two components have a fixed phaserelationship with each other.
 14. The system of claim 12 including: afirst phase discriminator for determining a first phase angle of a firstof the two signal components; a second phase discriminator fordetermining a second phase angle of a second of the two signalcomponents; and wherein the program code is further operable todetermine the coarse distance as the difference between the first phaseangle and the second phase angle.
 15. The system of claim 12 including:a mixer for generating a beat signal is derived by subtracting the twocomponents of the signal; a phase discriminator for determining a phaseangle of the beat signal; and wherein the program code is furtheroperable to determine the coarse distance from the phase angle of thebeat signal.
 16. The system of claim 15 further comprising: a receivercomprising at least two filters for receiving the signal and extractingtwo received signal components; a first phase discriminator fordetecting a first phase difference between at least one of the receivedsignal components and a corresponding component of a reference signalassociated with the signal; a mixer for mixing the two receivedcomponents to provide a virtual beat signal; a second phasediscriminator for detecting a second phase difference between the beatsignal and the virtual beat signal; and wherein the program code isfurther operable when executed to determine the fine distanceinformation in response to the first phase difference and the coarsedistance information in response to the second phase difference.
 17. Asystem for determining a position of an object with high resolution overa large area comprising: a first signal generator for generating a firstsignal; a second signal generator for generating a second signal, thesecond signal having a frequency relatively higher than the firstfrequency; means for determining a position of the object relative to anantenna including means for deriving coarse distance informationassociated with the antenna and the object and fine distance informationassociated with the antenna and the object using the first and secondsignals.
 18. The system of claim 17, further comprising: means, coupledto the first signal generator and the second signal generator, forgenerating a signal having two signal components that differ infrequency by a desired amount; and wherein the coarse distanceinformation is determined by subtracting phases of the two signalcomponents.
 19. The system of claim 17 wherein the first signal has along wavelength component and the second signal has a short wavelengthcomponent wherein the means for determining a position further includes:a mixer for mixing the first signal and the second signal to provide amixed signal; a transmitter for transmitting the mixed signal betweenthe object and the antenna; a filter for filtering the mixed signal toextract a received long wavelength component and a received short lengthcomponent; a first phase discriminator for determining a first phaseoffset between a long wavelength component of a first reference signalassociated with the first signal and the received long wavelength; asecond phase discriminator for determining a second phase offset betweena short wavelength component of a second reference signal associatedwith the second signal and the received short wavelength component; andwherein the first phase offset provides coarse distance information andthe second phase offset provides fine distance information.
 20. Thesystem of claim 17 wherein the means for determining the positionfurther includes: a first mixer for mixing the first and second signalsto provide a mixed signal; a filter for filtering the mixed signal toextract a transmission signal comprising two transmission signalcomponents, wherein the two transmission signal components are in fixedphase relationship with each other; a transmitter for transmitting thetransmission signal between the object and the antenna; a filter forfiltering the transmission signal to extract a received signalcomprising two received signal components; and a first phasediscriminator for determining a first phase difference between areference signal associated with at least one transmission signalcomponent and a corresponding received signal component to provide afirst phase difference, wherein the fine distance information is relatedto the first phase difference.
 21. The system of claim 20 furthercomprising: a second mixer for mixing the two transmission signalcomponents to provide a reference beat signal; a third mixer for mixingthe two received signal components to derive a virtual beat signal; anda second phase discriminator for determining a second phase differencebetween the reference beat signal and the virtual beat signal, whereinthe coarse distance information is related to the second phasedifference.
 22. The system of claim 20 further comprising: a secondphase discriminator for subtracting the phases of the received signalcomponents to determine the coarse distance information.
 23. The systemof claim 10, 12 or 17 wherein the system is a navigated medical system.